Ex vivo detection of rat coronary endothelial dysfunction in diabetes mellitus--methodological considerations.

The present state of knowledge unequivocally indicates that chronic diabetes is associated with impaired function of coronary vessels. Langendorff retrograde perfusion is one of the most frequently employed methods to study dysfunction of coronary vasculature in animal models of diabetes mellitus. However, because of methodological discrepancies in experimental protocols, the reliability of this technique is limited. In the current study, we propose the novel technique of vasoactive drug administration and aim to evaluate its usefulness in detecting coronary dysfunction in diabetes. Using Langendorff model, we compared the results of coronary endothelium-dependent (bradykinin) and -independent (diethylamine/nitric oxide, DEA/NO) vasodilatation obtained from experimental model utilizing automatically corrected-rate infusion with commonly used, constant-rate infusion of vasoactive drug. The infusion of bradykinin at constant rate failed to reveal coronary endothelium-dependent dysfunction typical for diabetes mellitus. Induction of endothelium-independent vasodilatation by constant infusion demonstrated augmented response in diabetic hearts. The administration of bradykinin or DEA/NO at the corrected rate was associated with significantly increased maximal responses in comparison with constant infusion experiments. This phenomenon was observed particularly in the control group. We conclude that only corrected-rate infusion of vasoactive agents to actual value of coronary flow enables the reliable detection of endothelial dysfunction in diabetes mellitus.

Antioxidative enzyme and glutathione S-transferase activities in diabetic rats exposed to long-term ASA treatment.

Low-dose acetylsalicylic acid (ASA) treatment is a standard therapeutic approach in diabetes mellitus for prevention of long-term vascular complications. The aim of the present work was to investigate the effect of long-term ASA administration in experimental diabetes on activities of some liver enzymes: glutathione peroxidase (GSHPx), catalase, glucose-6-phosphate dehydrogenase (G6PDH) and glutathione S-transferase (GST). Blood glucose, glycated hemoglobin, as well as plasma ALT and AST activities increased in rats with streptozotocin-induced experimental diabetes. The long-term hyperglycemia resulted in decreased activities of GSHPx (by 26%), catalase (by 34%), GST (by 38%) and G6PDH (by 27%) in diabetic animals. We did not observe increased accumulation of membrane lipid peroxidation products or altered levels of reduced glutathione in livers. The linear correlation between blood glucose and glycated hemoglobin in diabetic animals was distorted upon ASA treatment, which was likely due to a chemical competition between nonenzymatic protein glycosylation and protein acetylation. The long-term ASA administration partially reversed the decrease in GSHPx activity, but did not influence the activities of catalase and GST in diabetic rats. Otherwise, some decrease in these parameters was noted in ASA-treated nondiabetic animals. Increased ASA-induced G6PDH activity was recorded in both diabetic and nondiabetic rats. While both glycation due to diabetic hyperglycemia and ASA-mediated acetylation had very similar effects on the activities of all studied enzymes but G6PDH, we conclude that non-enzymatic modification by either glucose or ASA may be a common mechanism of the observed convergence.

Extracellular matrix remodeling in canine and mouse myocardial infarcts.

Extracellular matrix proteins not only provide structural support, but also modulate cellular behavior by activating signaling pathways. Healing of myocardial infarcts is associated with dynamic changes in the composition of the extracellular matrix; these changes may play an important role in regulating cellular phenotype and gene expression. We examined the time course of extracellular matrix deposition in a canine and mouse model of reperfused infarction. In both models, myocardial infarction resulted in fragmentation and destruction of the cardiac extracellular matrix, extravasation of plasma proteins, such as fibrinogen and fibronectin, and formation of a fibrin-based provisional matrix providing the scaffold for the infiltration of granulation tissue cells. Lysis of the plasma-derived provisional matrix was followed by the formation of a cell-derived network of provisional matrix composed of cellular fibronectin, laminin, and hyaluronic acid and containing matricellular proteins, such as osteopontin and osteonectin/SPARC. Finally, collagen was deposited in the infarct, and the wound matured into a collagen-based scar with low cellular content. Although the canine and mouse infarcts exhibited a similar pattern of extracellular matrix deposition, deposition of the provisional matrix was more transient in the mouse infarct and was followed by earlier formation of a mature collagen-based scar after 7-14 days of reperfusion; at the same timepoint, the canine infarct was highly cellular and evolving. In addition, mature mouse infarcts showed limited collagen deposition and significant tissue loss leading to the formation of a thin scar. In contrast, dogs exhibited extensive collagen accumulation in the infarcted area. These species-specific differences in infarct wound healing should be taken into account when interpreting experimental infarction studies and when attempting to extrapolate the findings to the human pathological process.